Contrasting Drydown Time Scales: SMAP L-Band vs. AMSR2 C-Band Brightness Temperatures Against Ground Observations and SMAP Products
2025
Hongxun Jiang | Shaoning Lv | Yin Hu | Jun Wen
Surface water loss, regulated by natural factors such as surface properties and atmospheric conditions, is a complex process across multiple spatiotemporal scales. This study compared the statistical characteristics of drydown time scale (&tau:) derived from multi-frequency microwave brightness temperatures (TB, including L-band and C-band), SMAP (Soil Moisture Active Passive) soil moisture (SM) products, and in situ observation data. It mainly conducted a sensitivity analysis of &tau: to depth, climate type, vegetation coverage, and soil texture, and compared the sensitivity differences between signals of different frequencies. The statistical results of &tau: showed a pattern varying with sensing depth: C-band TB (0~3 cm) <: L-band TB (0~5 cm) <: in situ observation (4~8 cm), i.e., the shallower the depth, the faster the drying. &tau: was sensitive to Normalized Difference Vegetation Index (NDVI) when NDVI <: 0.7 and climate types, but relatively insensitive to soil texture. The global median &tau: retrieved from TB aligned with the spatial pattern of climate classifications: drier climates and sparser vegetation coverage led to faster drying, and L-band TB was more sensitive to these factors than C-band TB. The attenuation magnitude of L-band TB was smaller than that of C-band TB, but the degree of change in its attenuation effect was greater than that of C-band TB, particularly regarding variations in NDVI and climate types. Furthermore, given the similar sensing depths of SMAP SM and L-band TB, their &tau: statistical characteristics were compared and found to differ, indicating that depth is not the sole reason SMAP SM dries faster than in situ observations.
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